KR20010070900A - Apparatus laying pipes underground for public engineering and construction - Google Patents

Abstract

PURPOSE: A buried pipe propelling and inserting apparatus for civil engineering works is provided to prevent the twisting and damage of an auger and to effectively discharge earth and sand through the auger by shortening the length of the auger. CONSTITUTION: A cylindrical casing(15) is connected with an inclined pipe(17). An auger(10) is inserted inside the casing. The auger is connected with an auger head(14) and protruded in the back of the casing. The back of the auger is connected with a shaft of a motor(18) inside a backup pipe(13). An earth discharging pump(19) is installed inside the backup pipe to discharge earth and sand from the casing. An earth discharging pipe(21) is connected with an outlet(20) of the earth discharging pump to discharge the earth and sand by penetrating the inside of a buried pipe(2).

Description

Apparatus laying pipes underground for public engineering and construction}

The present invention relates to a buried pipe propulsion insertion device for civil engineering to install a buried pipe horizontally through a lower part of a railroad, a road, a levee, a river, etc., and more specifically, to protrude and insert a buried pipe horizontally. An auger and a motor for driving the auger are installed inside the lead body of the buried pipe propulsion inserter, and the rear end of the auger allows the soil discharged backward through the auger to be discharged to the outside of the buried pipe. By installing a pump for earth and sand discharge, the discharge pipe for earth and sand discharge can be connected continuously to the rear end of the pump, so that the auger's length is shortened to prevent twisting and damage of the auger and effectively discharge the earth and sand discharged backward through the auger. To make it possible.

In general, in order to install water supply and sewage pipes, electric wires, and communication cables in the lower part of railroads, roads, banks, and rivers during civil engineering work, after embedding large burial pipes in the lower ground of roads, banks, rivers, etc. Install water and sewage pipes, wires and communication cables mentioned above.

As described above, in order to install water and sewage pipes, electric wires, and communication cables in the ground, a buried pipe such as a fume pipe or a steel pipe having a large diameter must be installed in the ground, and the installation process of a conventional general buried pipe is shown in FIG. Referring to (b) (c), it is as follows.

In order to embed the buried pipe in the ground, first, as shown in (a) of FIG. 1, the H-beam pile 3 is installed so that the sidewalls dug after digging the ground into the depth to be buried are formed. It is continuously driven into the side wall so that the soil of the side wall does not flow down.

After digging the ground in the form of a trench and preventing the soil from flowing down on both sides of the wall, a plurality of buried pipes (2) are arranged to be connected to each other in a trench-shaped excavation groove, and the plurality of buried pipes (2) thus listed are connected. Each buried pipe is connected by means, and after that, the H beam piles 3 which are embedded in both sides of the trench-type excavation groove are removed, and a plurality of buried pipes 2 are filled by filling the excavation groove with soil. To be buried in the ground as "1" in FIG. 1 represents a dike.

The conventional method of embedding a large number of buried pipes after digging in the form of trenches in this way directly cuts the ground, making it impossible to pass vehicles and pedestrians to the cut sections, causing traffic jams and increasing construction costs. There was a serious problem.

Accordingly, in view of the above problems, buried pipe propulsion inserting device and construction method for penetrating the buried pipe directly and horizontally into the ground without cutting the ground have been developed very usefully.

The conventional buried pipe propulsion insertion device 22 as described above, as shown in Figure 2, the upper portion of the rear of the bed (4) is installed on the bottom of the incision (entry entry: a) cut in the soil layer to insert the buried pipe The propulsion main body 6 which is slidably moved horizontally on the bed 4 by the hydraulic cylinder 5 is installed, and is pushed by the hydraulic cylinder 5 in front of the propulsion base 6 and the buried pipe 2 The propulsion plate 7 for pushing the pressure is provided.

In addition, an auger clamp 9 for rotating the auger 10 by rotating the motor 8 and clamping the rear end of the auger 10 is installed in the propulsion body 6 behind the propulsion plate 7. On the upper part of the bed 4, the leader 12 is inserted into a horizontal hole to excavate the soil layer horizontally is excavated and detachably installed.

The lead body 12 is provided with an auger head 14 for excavating the soil layer at the distal end of the backup pipe 13 propelled into the soil layer, and the backing pipe 13 at the rear end of the auger head 14 is backed up. The auger 10 in which the casing 15 was inserted in the outside over the full length of the pipe 13 is provided.

After excavating and inserting the soil layer by the lead body 12 into the horizontal hole, the auger 10 of the lead body 12 is separated from the auger clamp 9, and then the propulsion body 6 is retracted to retract the propulsion body. The buried pipe assembly 16 inserted and connected between the leading end of 6 and the rear end of the lead 12 is connected continuously.

The buried pipe assembly 16 is a buried pipe casing 11 connected to the casing 15 of the leader 12 in the buried pipe (2) connected to the backup pipe 13 of the leader (12) The auger 10 inserted over the full length of (2) and connected to the auger 10 of the lead body 12 is inserted in this casing 11.

When the buried pipe is to be inserted into the soil layer by the conventional buried pipe propulsion insertion device 22 configured as described above, as shown in FIGS. 2 and 3, one end of the soil layer on which the buried pipe is to be buried is excavated to enter and enter the port. (a) is formed, and the buried pipe propulsion insertion device 22 is installed in this oscillation entry port (a) (refer to (a) of FIG. 3).

At this time, the lead body 12 is mounted on the front bed 4 of the propulsion body 6 of the buried pipe propulsion insertion device 22, and in this state, the motor 8 installed in the propulsion body 6. When the hydraulic cylinder 5 is driven, the rotational force of the motor 8 is transmitted to the auger clamp 9 to rotate the auger clamp 9, and the auger clamp 14 has an auger head 14 at its distal end. Is equipped with auger (10) is rotated to excavate the soil layer, by the hydraulic cylinder (5) the propulsion plate (7) installed at the tip of the propulsion body (6) including the propulsion body (6) to the front. The back-up pipe 13 of the leader body 12 which is distal to the propelling plate 7 in contact with the propulsion plate 7 is moved forward.

As the auger head 14 rotates as described above and the backup pipe 13 moves horizontally forward, the soil layer is excavated in a circular shape by the auger head 14, and a diagram including the backup pipe 13 is formed in a horizontal hole. The sieve 12 is to be propelled and inserted, and the earth and sand generated during the excavation of the soil layer as the auger head 14 is pushed backward by the auger 10 in the casing 15, and the earth and sand discharge space behind the propulsion plate 7. It is discharged to 7a.

When the lead body 12 excavates the soil layer and is inserted into the horizontal hole formed in the soil layer, the rear end portion of the auger 10 is separated from the auger clamp 9, and the hydraulic cylinder 5 is operated backward so as to protrude the main body. (6) to the reverse to secure a space for the buried pipe assembly 16 can be inserted between the rear of the leading body (12) propelled into the soil layer and the front of the propulsion body (6).

After securing the space in which the buried pipe assembly 16 can be inserted between the rear of the lead body 12 and the front of the propulsion body 6 as described above, as shown in (b) of FIG. ) The lower end of the auger 10 of the buried pipe joint 16 into the space secured between the rear of the back and the front of the propulsion body 6, and the rear end of the auger 10 of the leader 12. The casing 15 of the lead body 12 and the tip of the casing 11 of the buried pipe joint 16 are connected to each other, and the rear end of the buried pipe joint 16 is an auger clamp 9 of the propelling body 6. To be clamped.

In addition, the hydraulic cylinder (5) is installed after detachably installing the rear end of the backup pipe (13) of the leader (12) and the buried pipe (2) of the buried pipe assembly (16), which are detachable by bolts or fittings. When the motor 8 is driven while operating, the rotational force of the motor 8 is transmitted to the auger 10 to rotate the auger head 14 installed at the tip of the lead body 12 to excavate the soil layer. The operation of the cylinder 5 causes the propulsion body 6 to move horizontally forward, so that the propulsion plate 7 moves horizontally forward with the propulsion body 6 to bury the buried pipe assembly 16. 2) Push the rear to the front so that the lead body 12 excavates the soil layer so that the buried pipe joint 16 connected to the lead body 12 from the lead body 12 is propelled into the horizontal hole formed by the excavation. Soil generated during the excavation of the soil layer is rear through the auger (10) Naohmyeonseo is pushed through the soil discharge space (7a) discharged to the outside.

The excavation of the soil layer by detachably connecting the buried pipe joint 16 to the rear of the lead body 12 and then pushing and inserting the soil layer after connecting the buried pipe joint 16 using only the lead body 12 from above. The process of repeatedly propelling the lead body 12 and the buried pipe assembly 16 into the horizontal hole formed by excavation is carried out repeatedly, and the buried pipe assembly 16 is connected to each other and the buried pipe is pushed horizontally into the soil layer. Buried while burying.

In this case, the plurality of buried pipe joints 16 are connected to the casing 11 and the auger 10 between the connection is made of detachable, but the connection between the buried pipe (2) is revealed that the connection by welding.

Propelled and buried as long as the length of the buried pipe (2) to be buried through the above process, when the lead body 12 arrives at the arrival port (b) of the arrival base, as shown in (d) to (bar) of FIG. As described above, the lead body 12 penetrating into the arrival port (b) is separated and recovered from the buried pipe assembly 16 at the foremost end, and inserted into the buried pipe 2 of each buried pipe assembly 16. When the auger 10 and the casing 11 outside the auger 10 are separated and recovered, each buried pipe 2 is horizontally embedded in the soil layer in a hollow state while being connected to each other by welding.

Since the plurality of buried pipes (2) buried in the soil layer is a hollow state can be used as a water and sewage pipe, or can be installed into the water and sewage pipe, electrical and communication cables, gas pipes and the like.

When the buried pipe is buried in the ground by the conventional buried pipe propulsion insertion device 22, since the soil layer is not cut, there is an effect that does not interfere with the traffic of the vehicle and the pedestrian at all.

However, this is because the augers 10 of the same length as the buried pipes 2 are continuously connected to the entire length of the buried pipes 2, so that the total connected length of the augers 10 is up to about 100 meters. Torque is generated in the auger 10, which is clamped to the auger clamp 9 of the propulsion body 6 and rotates, and the soil excavated by the auger head 14 by the auger 10 is rearward. As well as not being properly discharged, as the load is generated when the auger rotation had a problem that can not properly excavate the soil.

In order to solve the above problems, an auger and a motor capable of driving the auger are installed in a leader body of a buried pipe propulsion inserting device for horizontally pushing and inserting a buried pipe. Install the pump for earth and sand discharge to discharge the earth and sand discharged to the rear through the auger to the outside of the buried pipe, and the end of the pump can be connected to the discharge pipe for earth and sand discharged continuously, the length of the auger is shortened The technical task is to prevent twisting of the auger and its damage, and to effectively discharge the soil discharged backward through the auger.

The present invention for achieving the above object is installed on the rear upper portion of the bed so that the propulsion base can be moved horizontally by the hydraulic cylinder, excavation of the soil layer as an auger head while rotating by the power of the motor in front of the propulsion base body And discharge the earth and sand generated in the excavation process to the rear through the auger, and a leader inserted and pushed by the hydraulic cylinder into the horizontal hole excavated by the auger head. In the case of laying the buried pipe horizontally on the soil layer while retracting the propulsion body by inserting the buried pipe between the leading end of the propulsion body and the rear end of the lead body, the burr pipe is placed behind the inclined pipe inserted inside the leading end of the lead body. A casing in the form of a cylindrical tube shorter than the backup pipe is connected, and the casing Inside the front end is connected to the rear end of the auger head, the rear end is inserted into the auger protruding to the rear end of the casing, the rear end of the auger is connected to the shaft of the motor installed inside the backup pipe, the back of the backup pipe of the casing An earth and sand discharge pump for discharging the earth and sand discharged through the casing to the rear is installed, and the earth and sand discharge pipe for discharging the soil to the rear through the inside of the buried pipe is connected to the discharge port of the earth and sand discharge pump. .

Figure 1 (a) (b) (c) is an explanatory diagram showing the installation process of the buried pipe during civil engineering works such as levees.

Figure 2 is a side cross-sectional view showing a conventional buried pipe propulsion insertion device.

Figure 3 (a) to (bar) is an explanatory diagram showing a process of installing a buried pipe using a conventional buried pipe propulsion inserting device.

Figure 4 is a side cross-sectional view showing a buried pipe propulsion insertion apparatus according to the present invention.

5 is an enlarged cross-sectional view of a portion “A” of FIG. 4.

6 is a view showing a soil discharge pipe that is a major component of the present invention.

<Explanation of symbols for main parts of drawing>

1 Dike 2 Buried Pipe 3 H Beam File

4: bed 5: hydraulic cylinder 6: propulsion body

7 propulsion plate 8 motor 9 auger clamp

10: Auger 11: Casing 12: Leader

13: Backup pipe 14: August head 15: Casing

16: buried pipe assembly 17: inclined pipe 18: motor

19: soil discharge pump 20: outlet 21: soil discharge pipe

Hereinafter, with reference to the accompanying drawings Figures 4 and 5 for the civil engineering buried pipe propulsion insertion apparatus according to the present invention.

The buried pipe propulsion insertion device for civil engineering according to the present invention, the propulsion main body (6) capable of horizontally sliding movement by the hydraulic cylinder (5) on the rear upper portion of the bed (4) having a guide rail in the longitudinal direction on both sides of the upper surface And a propulsion plate 7 pushed by the hydraulic cylinder 5 and pushing the buried pipe 2 in front of the propulsion body 6, and a propulsion body 6 behind the propulsion plate 7. ) Is provided with an auger clamp 9 that rotates by a motor 8 and clamps the rear end of the auger 10.

And, in the upper part of the bed (4), the leader 12 which is inserted into the horizontal hole is excavated horizontally excavating the soil layer is installed detachably, the soil layer is excavated by the leader 12 to the horizontal hole After propulsion insertion, the auger 10 of the lead body 12 is removed from the auger clamp 9, and then the propulsion body 6 is retracted and inserted between the leading end of the propulsion body 6 and the rear end of the lead body 12. The buried pipe 2 which connects by making it connect is made to connect continuously.

The leading body 12 is provided with a wide inclined tube 17 having a wide front and a narrow rear in the front end portion of the backup pipe 13 formed in the shape of a cylindrical tube, and a cylindrical casing 15 at the rear of the inclined tube 17. ) Is connected, the auger head 14 is inserted into the tip end of the inclined tube 17, and the auger 10 is inserted into the casing 15 so that the tip end of the auger 10 is auger head ( It is connected to the rear end of 14).

The rear end of the auger 10 is connected to the shaft of the motor 18 installed inside the backup pipe 13, and is discharged through the casing 15 inside the backup pipe 13 behind the casing 15. A soil discharge pump 19 for discharging soil to the rear is provided.

At this time, the overall length of the lead body 12 is made of 2.5 to 3.5M, the length of the casing 15 into which the auger 10 installed in the inside of the lead body 12 is inserted is the length of the lead body 12. Shorter than the total length, both the motor 18 and the soil discharge pump 19 are installed inside the backup pipe (13).

In addition, the inside of the buried pipe 2 connected to the rear of the lead body 12 after the lead body 12 is excavated and inserted into the horizontal hole in the discharge port 20 of the soil discharge pump 19. The earth and sand discharge pipe 21 for penetrating and discharging the soil to the rear is connected.

The leading end of the leading buried pipe 2 directly connected to the rear end of the lead body 12 is formed to be stepped into the rear end of the backup pipe 13, and the leading end of the leading buried pipe 2 has a backup pipe. The connection between the rear end buried pipe 2 and the end buried pipe 2, which is inserted into the rear end of (13) and is joined as a bolt and is continuously connected to the rear end of the leading buried pipe 2, is welded in a state where the connecting portions are in contact with each other. Are combined.

Each of the buried pipes 2 preferably has a total length of 2.5 to 3.5 M, but can be produced to a length of 5 to 6 M, if necessary.

In addition, the earth and sand discharge pipe 21 connected to the outlet 20 of the earth and sand discharge pump 19 is the same length as the buried pipe (2) in the state having a flange portion (21a) at both ends as shown in FIG. Each time the buried pipe 2 is connected to the metal pipe, each soil discharge pipe 21 can be connected as a bolt.

In addition, the soil discharge pipe 21 may be used by connecting a long flexible pipe as another example, the length of the flexible pipe 50 to 60M, 70 to 80M, 90 to 100M for the work site It can be selected and used appropriately.

Then, the power supply line for supplying power to the motor 18 and the earth and sand discharge pump 19 is lengthened by about 100 meters so that power is supplied from the propulsion body 6 to the motor 18 and the earth and sand discharge pump 19. To be supplied.

Reference numeral 23 in the reference numerals denotes electric wires for supplying power to the motor 18 and the soil discharge pump 19.

Referring to Figures 4 to 6 the operational relationship of the present invention configured as described above is as follows.

As described above, when the buried pipe is to be inserted and pushed into the soil layer by using the buried pipe propulsion insertion device 22 of the present invention, one side of the soil layer on which the buried pipe is to be buried is excavated to form an oscillation entry port (a), A buried pipe propulsion insertion device 22 is installed in this oscillation entry port (a).

At this time, the lead body 12 is mounted on the front bed 4 of the propulsion body 6 of the buried pipe propulsion insertion device 22, and in this state, the motor 18 installed in the lead body 12. When the hydraulic cylinder 5 installed in the propulsion body 6 is driven, the rotational force of the motor 18 is transmitted to the auger 10 and the auger head 14, and the auger 10 and the auger head 14. ), The rotating auger head 14 excavates the soil layer, and the hydraulic cylinder 5 is provided at the tip of the propulsion body 6 including the propulsion body 6 by the hydraulic cylinder 5. (7) is moved horizontally forward, so that the backup pipe 13 of the lead body 12 whose distal end contacts the propulsion plate 7 is pushed forward.

As the auger head 14 rotates as described above and the backup pipe 13 moves horizontally forward, the soil layer is excavated in a circular shape by the auger head 14, and a diagram including the backup pipe 13 is formed in a horizontal hole. Sieve 12 is to be propelled.

Soil generated when the soil layer is excavated as the auger head 14 is introduced into the inclined tube 17 as the entire lead 12 moves forward while the auger head 14 rotates, and the inclined tube 17 Soil flowing into the) is discharged to the back of the backup pipe 13 while being pushed to the rear of the casing 15 from the inside of the casing 15 by the rotating auger (10).

When the earth and sand is discharged to the rear of the casing 15 as described above, the earth and sand discharge pipe 21 connected to the outlet 20 of the earth and sand discharge pump 19 by sucking the soil by the pumping force of the earth and sand discharge pump 19. It will be discharged to the outside.

When the lead body 12 excavates the soil layer and is inserted into the horizontal hole formed in the soil layer, the hydraulic cylinder 5 is operated backward so that the propulsion base body 6 moves backward so that the lead body 12 is pushed into the soil layer. Secure a space for the buried pipe (2) can be inserted between the rear of the) and the front of the propulsion body (6).

After securing the space in which the buried pipe 2 can be inserted between the rear of the lead body 12 and the front of the propulsion body 6 as described above, the rear of the lead body 12 and the front of the propulsion body 6. The buried pipe 2 is lowered to the space secured therebetween and connected to the front end of the buried pipe 2 and the rear end of the lead body 12.

At this time, the tip buried pipe 2 directly connected to the rear end of the conductor 12 forms a stepped portion as shown in FIG. 5, so that the stepped portion of the tip buried tube 2 is a backup pipe 13 of the leader 12. After inserting into the rear end, it is detachably connected by bolts.

After the tip buried pipe 2 is connected to the rear end of the lead body 12, the motor 18 is driven while operating the hydraulic cylinder 5, and the rotational force of the motor 8 is led through the auger 10. The soil layer is excavated by rotating the auger head 14 installed at the front end of the sieve 12, and by operating the hydraulic cylinder 5, the propulsion base 6 is moved horizontally to the forward direction. 7) The propulsion plate 7 pushes the rear end of the buried pipe 2 forward while horizontally moving forward with the propulsion body 6.

As the auger head 14 rotates as described above, the soil layer is excavated, and the end buried pipe 2 connected to the lead body 12 is propelled and inserted into the horizontal hole formed by the excavation. , Soil generated in the process of excavating the soil layer is pushed out of the rear of the casing 15 through the interior of the inclined tube 17 and the casing 15 by the rotation of the auger 10, thus the casing 15 Soil is pushed out to be discharged to the outside through the soil discharge pipe 21 by the pumping force of the soil discharge pump (19).

After the leading buried pipe 2 connected to the rear of the lead body 12 and the lead body 12 is pushed and inserted into the soil layer, the hydraulic cylinder 5 is operated to back the propulsion body 6 back to the rear, Between the rear end of the buried pipe (2) and the front of the propulsion body (6) is provided a space for inserting another rear buried pipe (2).

As described above, the buried pipe 2 and one buried pipe 2 are propelled and inserted into the soil layer, and the propulsion body 6 is retracted so that between the tip end of the propulsion body 6 and the rear end of the tip buried pipe 2 is further removed. After providing a space for inserting another trailing buried pipe (2), the other end of the buried pipe (2) and the tip of the trailing buried pipe (2) are fitted with each other while inserting another buried pipe (2) into this space. Weld and join the mated contacts behind them.

When connecting another buried pipe (2), it is natural that the electric wires for supplying power to the motor (18) and the soil discharge pump (19) must be able to escape to the propulsion body (6) side, the new buried pipe (2) Whenever it is connected to the soil discharge pipe (21) connected to the outlet 20 of the soil discharge pump 19 should also be able to discharge the soil to the outside through the interior of the buried pipe (2) newly connected.

At this time, the soil discharge pipe 21 is provided with a flange portion (21a) on both sides as shown in Figure 6, if formed of a metal pipe equal to the length of the buried pipe (2) each time a new buried pipe (2) is connected newly In the interior of the buried pipe (2) to be connected to the buried pipe (2) having a flange portion (21a) on both sides to be connected to the soil discharge pipe (21) of the front end as a bolt.

As described above, after the new buried pipe 2 is welded and the electric wire and the earth discharge pipe 21 penetrate backward, the hydraulic cylinder 5 is protruded forward to move the propulsion body 6 horizontally forward. The auger 10 and the auger head are operated by operating the motor 18 installed at the rear of the auger 10 while pushing the rear of the buried pipe 2 newly connected to the propulsion plate 7 installed in front of the propulsion body 6. Rotating the 14 causes the auger head 14 to excavate the soil layer, and the soil generated in the process of excavating the soil layer by the auger head 14 is discharged to the rear end of the casing 15 by the auger 10. The soil is discharged to the outside through the soil discharge pipe 21 by the pumping force of the soil discharge pump (19).

In this way, the plurality of buried pipes 2 are continuously connected to each other while the propellant is inserted into the soil layer, and the lead body 12 and the plurality of buried pipes 2 are propelled and inserted to the destination so that the lead body 12 protrudes into the arrival port (b). When it comes out, the lead body 12 which protrudes in the arrival port (b) is collect | recovered separately from the buried pipe 2 of the uppermost stage. At this time, the electric wires for supplying power to the motor 18 and the earth and sand discharge pump 19 are removed from the propulsion body 6 and separated, and when the earth and sand discharge pipe 21 is flexible, the lead body 12 in the arrival port (b). ), The wire and the flexible soil discharge pipe 21 is recovered together with the leader (12).

In the case where the soil discharge pipe 21 is a metal pipe, the lead body 12 is moved forward in a state in which the lead body 12 is separated from the buried pipe 2 at the uppermost end buried horizontally in the tubing layer. 12) and the front end of the buried pipe (2) of the uppermost end and the worker's body is moved so that the body of the worker in the gap between the opening and discharge outlet 20 of the earth and sand discharge pump (19) The lead body 12 is collected in a state in which the earth and sand discharge pipe 21 made of a metal pipe is separated.

After recovering the lead body 12, the earth and sand discharge pipe 21 is separated by separating the flange portions 21a one by one while pulling out the earth and sand discharge pipe 21 made of a metal pipe from the arrival port (b) or the oscillation entry port (a). It will be separated, the interior of the buried pipe (2) is connected to a plurality of empty state.

Since the plurality of buried pipes 2 horizontally buried in the soil layer as described above is hollow, it can be used as a water and sewage pipe, or the water and sewage pipe, electric and communication cables, gas pipes, etc. can be installed therein.

The buried pipe propulsion insertion device for civil engineering of the present invention as described above is provided with an auger and a motor capable of driving the auger inside the lead body of the buried pipe propulsion inserting device, and the auger is provided at the rear end of the auger. Install a soil pump for discharging the soil to be discharged to the outside of the buried pipe to the outside of the buried pipe, and the rear end of the pump can be connected to the discharge pipe for soil discharge continuously, the auger is short It is effective to prevent the damage caused by the torsion and to effectively discharge the soil discharged backward through the auger.

In addition, in the conventional buried pipe propulsion insertion device is inserted both the auger and the auger is inserted into the interior of the buried pipe continuously connected to the rear end of the leader, so each time the buried pipe is connected in addition to the twist of the auger mentioned above Although casing and auger are continuously connected, in the present invention, since the auger and the casing are not inserted into the buried pipe connected to the rear of the lead body, the process of connecting the auger and the casing is deleted, thereby reducing the work time. And, a large amount of augers and casings are unnecessary, which reduces the cost of construction, and the conventional propulsion body transmits the auger clamps and the motors capable of rotating the auger clamps to the auger clamps. It takes a power transmission device, but in the present invention such devices are unnecessary because of the propeller The structure of the main body is simplified and the manufacturing cost of equipment is reduced.

Claims (1)

The propulsion body 6 is installed on the rear upper part of the bed 4 to be slidably moved horizontally by the hydraulic cylinder 5, and the front of the propulsion body 6 is rotated by the power of a motor while the auger head is rotated. (12) the leading body 12 which is excavated and discharged to the rear through the auger (10) generated in the excavation process and pushed by the hydraulic cylinder (5) into a horizontal hole excavated by the auger head (14) After the propellant body 12 and the propelling body 6 which are propelled and inserted into the horizontal hole are separated, the propelling body 6 is retracted, and between the leading end of the propelling body 6 and the rear end of the leading body 12. In embedding buried pipe 2 horizontally in soil layer while inserting buried pipe 2, and connecting, A casing 15 in the form of a cylindrical tube having a length shorter than that of the backup pipe 13 is connected to the rear of the inclined tube 17 inserted into the front end of the lead body 12, and the front end of the casing 15. Is connected to the rear end of the auger head 14, the rear end is inserted into the auger 10 protruding to the rear end of the casing 15, the rear end of the auger 10 is a motor installed inside the backup pipe 13 It is connected to the shaft of (18), inside the back-up pipe 13 of the casing 15 is provided with a soil discharge pump 19 for discharging the soil discharged through the casing 15 to the rear, Civil engineering works buried pipe propulsion insertion device, characterized in that the discharge port 20 of the soil discharge pump (19) is connected to the soil discharge pipe (21) for discharging the soil by passing through the interior of the buried pipe (2).